Project description:A total of 11,308 single nuclei were sequenced. After quality filtering (Methods, Supplementary Fig. 3A, 4A-4C), 11,090 high-quality nuclei were obtained, including 5,336 cells from EB2-flox mouse and 5,754 from EB2-vGATCre mouse. These nuclei were grouped into 17 cell clusters (Supplementary Fig. 4D-4H), which were further assigned to 9 major cell types based on cell-type-specific markers: excitatory neurons (Slc17a7+), inhibitory neurons (Gad2+), astrocytes (Gja1+), microglia (C1qa+), oligodendrocytes (Aspa+), oligodendrocyte precursors (Pdgfra+), smooth muscle cell (Uaca+), endothelial (Flt1+) and ependymal (Dynlrb2+) cells (Fig. 4A, 4C, supplementary Fig. 3B).

Project description:PPARγ is known for its anti-inflammatory actions in macrophages. However, which macrophage populations express PPARγ in vivo and how it regulates tissue homeostasis in the steady state and during inflammation is not completely understood. We show that lung and spleen macrophages constitutively expressed PPARγ, while other macrophage populations did not. Recruitment of monocytes to sites of inflammation was associated with induction of PPARγ as they differentiated to macrophages. Its absence in these macrophages led to failed resolution of inflammation, characterized by persistent, low-level recruitment of leukocytes. Conversely, PPARγ agonists supported an earlier cessation in leukocyte recruitment during resolution of acute inflammation and likewise suppressed monocyte recruitment to chronically inflamed atherosclerotic vessels. In the steady state, PPARγ deficiency in macrophages had no obvious impact in the spleen but profoundly altered cellular lipid homeostasis in lung macrophages. Reminiscent of pulmonary alveolar proteinosis, LysM-Cre x PPARγflox/flox mice displayed mild leukocytic inflammation in the steady-state lung and succumbed faster to mortality upon infection with S. pneumoniae. Surprisingly, this mortality was not due to overly exuberant inflammation, but instead to impaired bacterial clearance. Thus, in addition to its anti-inflammatory role in promoting resolution of inflammation, PPARγ sustains functionality in lung macrophages and thereby has a pivotal role in supporting pulmonary host defense. The two major subsets of monocytes (Ly-6C+ and Ly-6Clo) from 12-week old C57Bl/6 mice were sorted and the RNA extracted and hybridized to Affymetrix GeneChip® 430 2.0 arrays. We pooled leukocytes from 5 mice for each sort and sorted 3 to 4 separate times for 3 to 4 biological replicates.

Project description:Group 2 innate lymphoid cells (ILC2s) play critical roles in driving the pathogenesis of allergic airway inflammation. The mechanisms underlying the regulation of ILC2s remain to be fully understood. Here, we identified neuropilin-1 (Nrp1) as a surface marker of ILC2s in response to IL-33 stimulation. Nrp1 was abundantly expressed in ILC2s from lung under steady state, which was significantly reduced upon IL-33 stimulation. ILC2s with high expression of Nrp1 (Nrp1high) displayed lower response to IL-33, as compared with Nrp1low ILC2s. Transcriptional profiling and flow cytometric analysis showed that downregulation of AKT-mTOR signaling participated in the diminished functionality of Nrp1high ILC2s. These observations revealed a potential role of Nrp1 in ILC2s responses under allergic inflammatory condition.

Project description:Cell-in-cell (CIC) structures have been suggested to mediate intracellular substance transport between cells and have been found widely in inflammatory lung tissue of asthma. The aim of this study was to investigate the significance of CIC structures in inflammatory progress of asthma. CIC structures and related inflammatory pathways were analyzed in asthmatic lung tissue and normal lung tissue of mouse model. In vitro, the activation of inflammatory pathways by CIC mediated intercellular communication was analyzed by RNA-Seq and verified by western blotting and immunofluorescence. Results showed CIC structures of lymphocytes and alveolar epithelial cells in asthmatic lung tissue mediated intercellular substance (such as mitochondria) transfer and promoted pro-inflammation in two phases. At early phase, internal lymphocytes triggered inflammasome dependent pro-inflammation and cell death of itself. Then degraded lymphocytes released cellular contents such as mitochondria inside alveolar epithelial cells, further activated multi-pattern-recognition receptors and NF-kappa Bsignalingpathways of alveolar epithelial cells, thereby amplified pro-inflammatory response in asthma. Our work supplements the mechanism of asthma pro-inflammation progression from the perspective of CIC structure of lymphocytes and alveolar epithelial cells, and provides a new idea for anti-inflammatory therapy of asthma.

Project description:Platelets, traditionally recognized for their involvement in hemostasis and wound healing, also play a central role in immune regulation and inflammation. Their function and production adapt in response to inflammatory cues such as cytokines and danger-associated molecular patterns. Interleukin-33 (IL-33), an alarmin released during tissue damage, particularly in lung inflammation, has been implicated in influencing platelet biology, though its exact effects remain poorly understood. To clarify IL-33’s role, we examined its impact on platelet proteome. We first compared the proteome of platelets purified by FACS from IL-33-deficient (IL-33KO) mice versus WT mice (n=5 biological replicates in each group, 10 raw MS files). We also compared the proteome of platelets from WT mice which were either non stimulated (n= 8 biological replicates) or treated intranasally with recombinant IL-33 (n= 9 biological replicates).

Project description:Summary: Blocking IL-33 signaling ameliorates inflammation, tissue remodeling and preserves lung function in a model of persistent and exacerbating airway disease. Background: Severe inflammatory airway diseases are associated with inflammation that fails to resolve, leading to structural changes and an overall environment primed for exacerbations. Objective: We sought to identify and inhibit pathways that perpetuate this heightened inflammatory state, as this could lead to therapies that allow for a more quiescent lung, less predisposed to symptoms and exacerbations. Methods: Using prolonged exposure to house dust mite (HDM) in mice, we developed a mouse model of persistent and exacerbating airway disease characterized by a mixed inflammatory phenotype. Results: We show that lung IL-33 drives inflammation and remodeling beyond the type 2 response classically associated with IL-33 signaling. IL-33 blockade with an IL-33 neutralizing antibody normalized established inflammation, and improved remodeling of both the lung epithelium and lung parenchyma. Specifically, IL-33 blockade normalized persisting and exacerbating inflammatory endpoints, including eosinophilic, neutrophilic and ST2+ CD4+ T cell infiltration. Importantly, we identified a key role for IL-33 in driving lung remodeling, as anti-IL-33 also reestablished the presence of ciliated cells over mucus producing cells and lowered myofibroblast numbers, even in the context of continuous allergen exposure, resulting in improved lung function. Conclusion: Overall, this study shows that elevated IL-33 drives a self-perpetuating amplification loop that retains the lung in a state of lasting inflammation and remodeled tissue, primed for exacerbations. Thus, IL-33 blockade may ameliorate symptoms and prevent exacerbations by quelling persistent inflammation and airway remodeling.

Project description:Resident tissue macrophages and monocytes (RTMs) integrate local and systemic signals to coordinate immune cell function at homeostasis and in response to inflammatory stimuli. Obesity-associated metabolic dysfunction drives the development of RTM populations that contribute to disease states in multiple tissues. However, the contribution of specific dietary components to innate immune cell activation and function, as opposed to the effects of obesity per se, is largely unknown. Herein, we studied the mechanisms by which high fat (HF) diets shape lung RTM phenotype and function in the steady state and influence responses to inflammatory insults. We report that during HF diet feeding, lung RTMs accumulate saturated long chain fatty acids (LCFA), specifically stearic acid (SA), and demonstrate features of NLRP3 inflammasome priming and activation. In vivo, increased dietary SA was sufficient to cause neutrophil-predominant lung inflammation in the steady state and exacerbate a model of innate airway inflammation, while increased dietary oleic acid, the monounsaturated counterpart of SA, was sufficient to reduce inflammasome activation in the steady state and attenuate airway inflammation. Importantly, depletion of IL-1β or pharmacologic inhibition of the endonuclease IRE1⍺ protected against SA-induced exacerbated lung inflammation. Finally, we identified a population of lung monocytes with hallmarks of HF diet-induced RTM activation that are present in obese humans with asthma. Together, these results identify a class of dietary lipids that regulate lung RTM phenotype and function in the steady state and modulate the severity of inflammation in the lung.

Project description:As opposed to their well-characterized contributions to inflammatory processes, tissue eosinophils are now also thought to contribute to immune homeostasis at mucosal sites such as the gut. Yet, whether such steady-state eosinophils exist in the lung is currently unclear. In this project, we identified and characterized lung resident eosinophil and also studied what happen to these cell during a mouse model of allergic inflammation (House dust mite (HDM) exact administrations). We compared the transcriptional profile of lung resident eosinophil from naive mice (rEOS ss) or from HDM-treated mice (rEOS i) and of inflammatory eosinophil (iEOS) from HDM-treated mice.

Project description:PPARγ is known for its anti-inflammatory actions in macrophages. However, which macrophage populations express PPARγ in vivo and how it regulates tissue homeostasis in the steady state and during inflammation is not completely understood. We show that lung and spleen macrophages constitutively expressed PPARγ, while other macrophage populations did not. Recruitment of monocytes to sites of inflammation was associated with induction of PPARγ as they differentiated to macrophages. Its absence in these macrophages led to failed resolution of inflammation, characterized by persistent, low-level recruitment of leukocytes. Conversely, PPARγ agonists supported an earlier cessation in leukocyte recruitment during resolution of acute inflammation and likewise suppressed monocyte recruitment to chronically inflamed atherosclerotic vessels. In the steady state, PPARγ deficiency in macrophages had no obvious impact in the spleen but profoundly altered cellular lipid homeostasis in lung macrophages. Reminiscent of pulmonary alveolar proteinosis, LysM-Cre x PPARγflox/flox mice displayed mild leukocytic inflammation in the steady-state lung and succumbed faster to mortality upon infection with S. pneumoniae. Surprisingly, this mortality was not due to overly exuberant inflammation, but instead to impaired bacterial clearance. Thus, in addition to its anti-inflammatory role in promoting resolution of inflammation, PPARγ sustains functionality in lung macrophages and thereby has a pivotal role in supporting pulmonary host defense.

Project description:Supporting MS data for paper (doi: 10.1038/s41586-024-07073-0) by DaRosa P.A., Penchev I. et al., titled "UFM1 E3 ligase promotes recycling of 60S ribosomal subunits from the ER". Index of MS supporting files uploaded: - Related to Fig. 1a and Extended Data Fig. 1a (AO3435-AO3440: TMT proteomics (Unimod: 35; 737; 4)). - Related to Fig. 1b, c (see MSV000093721).